105,213 research outputs found
Impact of parasitoid-associated polydnaviruses on plant-mediated herbivore interactions
Insect herbivores interact via plant-mediated interactions in which one herbivore species induces changes in plant quality that affects the performance of a second phytophagous insect that shares the food plant. These interactions are often asymmetric due to specificity in induced plant responses to herbivore attack, amount of plant damage, elicitors in herbivore saliva and plant organ damaged by herbivores. Parasitoids and their symbiotic polydnaviruses alter herbivore physiology and behaviour and may influence how plants respond to parasitized herbivores. We argue that these phenomena affect plant-mediated interactions between herbivores. We identify that the extended phenotype of parasitoid polydnaviruses is an important knowledge gap in interaction networks of insect communities
N-doped TiO2 nanoparticles: photocatalytic degradation of ethanol and acetaldehyde in the gas phase
Getting confused: learning reduces parasitoid foraging efficiency in some environments with non-host-infested plants
Foraging animals face the difficult task to find resources in complex environments that contain conflicting information. The presence of a non-suitable resource that provides attractive cues can be expected to confuse foraging animals and to reduce their foraging efficiency. We used the parasitoid Cotesia glomerata to study the effect of non-host-infested plants and associative learning on parasitoid foraging efficiency. Inexperienced C. glomerata did not prefer volatiles emitted from host (Pieris brassicae)-infested plants over volatiles from non-host (Mamestra brassicae)-infested plants and parasitoids that had to pass non-host-infested plants needed eight times longer to reach the host-infested plant compared to parasitoids that had to pass undamaged plants. Contrary to our expectations, oviposition experience on a host-infested leaf decreased foraging efficiency due to more frequent visits of non-host-infested plants. Oviposition experience did not only increase the responsiveness of C. glomerata to the host-infested plants, but also the attraction towards herbivore-induced plant volatiles in general. Experience with non-host-infested leaves on the contrary resulted in a reduced attraction towards non-host-infested plants, but did not increase foraging efficiency. Our study shows that HIPVs emitted by non-host-infested plants can confuse foraging parasitoids and reduce their foraging efficiency when non-host-infested plants are abundant. Our results further suggest that the effect of experience on foraging efficiency in the presence of non-host-infested plants depends on the similarity between the rewarding and the non-rewarding cue as well as on the completeness of information that parasitoids have acquired about the rewarding and non-rewarding cues.</p
Photocatalytic removal of ethanol and acetaldehyde by N-promoted TiO2 films: the role of the different nitrogen sources
Pure and N-doped TiO2 nanoparticles are obtained by a combination of wet and thermal procedures, starting from TiCl3 and alkoxide precursors; the N-source is both inorganic (NH3) and organic (triethylamine). Samples are characterized for their bulk, surface, optical and magnetic properties. Ab initio calculations of the electronic properties of the doped samples are performed. Sample thin films are tested for their photocatalytic activity, under UV and simulated solar irradiation, with respect to air pollutants ethanol and acetaldehyde. Both the disappearance of the molecule itself and the complete mineralization (CO2) are followed during the reaction time. FTIR/ATR analyses are performed on samples withdrawn during the course of the reaction to identify reaction intermediates. In the case of acetaldehyde, photocatalytic tests are also performed under visible light (λ > 400 nm). The photoactivity sequences of the N-doped samples under the different irradiation sources are discussed with reference to their surface/bulk properties, light absorption features, nature and amount of paramagnetic species
Gone with the wind : low availability of volatile information limits foraging efficiency in downwind-flying parasitoids
Parasitoids need to find their plant-feeding hosts in complex environments that contain multiple other plant and insect species. They usually rely on herbivore-induced plant volatiles to locate herbivore-infested plants from a distance and their foraging efficiency may be reduced when volatile information is not available. Downwind foraging during times when high wind speeds prevent odour-guided upwind flights may create foraging situations with limited accessibiliy to volatile information. We hypothesized that parasitoids forage less efficiently by landing on nonhost-damaged or undamaged plants when they are forced to fly downwind and tested this in a wind tunnel experiment. We released the parasitoid Cotesia glomerata (Hymenoptera, Braconidae) either upwind or downwind of a plant stand and observed their foraging behaviour. During downwind foraging, parasitoids were less successful in host finding and needed more time until they managed to oviposit in a host caterpillar compared to the upwind foraging situation. The observed increase in foraging time was caused by prolonged foraging on nonhost-infested and undamaged plants in the downwind situation, indicating that parasitoids leave an unprofitable patch that does not contain host caterpillars earlier, when they perceive volatiles from other herbivore-infested plants located upwind. Volatile information on the availability of herbivore-infested plants within a plant stand seems to be crucial for efficient foraging in plant stands that contain a mixture of host-infested, nonhost-infested and undamaged plants. Parasitoid foraging efficiency may thus be strongly reduced when high wind speed prevents odour-guided upwind flight
Adverse weather conditions impede odor-guided foraging of parasitoids and reduce their host-finding success
Den h. Aloysius de Gonzagua, voorgesteld tot spielgel van een heylig leven [...] /
Cf. De Backer-Sommervogel 5, 730, 2 for author and for other Dutch editions. Format acc. to Vander HaeghenVander Haeghen Bib gant. 9196Europeana-GoogleBook
Microbial symbionts of parasitoids
Parasitoids depend on other insects for the development of their offspring. Their eggs are laid in or on a host insect that is consumed during juvenile development. Parasitoids harbor a diversity of microbial symbionts including viruses, bacteria, and fungi. In contrast to symbionts of herbivorous and hematophagous insects, parasitoid symbionts do not provide nutrients. Instead, they are involved in parasitoid reproduction, suppression of host immune responses, and manipulation of the behavior of herbivorous hosts. Moreover, recent research has shown that parasitoid symbionts such as polydnaviruses may also influence plant-mediated interactions among members of plant-associated communities at different trophic levels, such as herbivores, parasitoids, and hyperparasitoids. This implies that these symbionts have a much more extended phenotype than previously thought. This review focuses on the effects of parasitoid symbionts on direct and indirect species interactions and the consequences for community ecology
Hyperparasitoids exploit herbivore-induced plant volatiles during host location to assess host quality and non-host identity
Although consumers often rely on chemical information to optimize their foraging strategies, it is poorly understood how top carnivores above the third trophic level find resources in heterogeneous environments. Hyperparasitoids are a common group of organisms in the fourth trophic level that lay their eggs in or on the body of other parasitoid hosts. Such top carnivores use herbivore-induced plant volatiles (HIPVs) to find caterpillars containing parasitoid host larvae. Hyperparasitoids forage in complex environments where hosts of different quality may be present alongside non-host parasitoid species, each of which can develop in multiple herbivore species. Because both the identity of the herbivore species and its parasitization status can affect the composition of HIPV emission, hyperparasitoids encounter considerable variation in HIPVs during host location. Here, we combined laboratory and field experiments to investigate the role of HIPVs in host selection of hyperparasitoids that search for hosts in a multi-parasitoid multi-herbivore context. In a wild Brassica oleracea-based food web, the hyperparasitoid Lysibia nana preferred HIPVs emitted in response to caterpillars parasitized by the gregarious host Cotesia glomerata over the non-host Hyposoter ebeninus. However, no plant-mediated discrimination occurred between the solitary host C. rubecula and the non-host H. ebeninus. Under both laboratory and field conditions, hyperparasitoid responses were not affected by the herbivore species (Pieris brassicae or P. rapae) in which the three primary parasitoid species developed. Our study shows that HIPVs are an important source of information within multitrophic interaction networks allowing hyperparasitoids to find their preferred hosts in heterogeneous environments
- …
